DE4428461A1 - Process for the production of dinitrotoluene - Google Patents

Description

The present invention relates to the production of dinitrotoluene by nitria tion of toluene with nitrating acid under adiabatic conditions.

It is known to convert toluene into dinitrotoluene (DNT) in an adiabatic way (EP-A 597 361). Here, toluene with at least 2 equivalents a nitrating acid of a certain composition in an adiabatic way implemented, a final temperature of over 120 ° C is reached. To Separation of the phases at this temperature becomes an acid phase Concentration (flash evaporation in vacuum) supplied, the heat content the acid is used for concentration. The concentrated acid is with Nitric acid replenished and returned to the process.

This method has the difficulty that with the distilling Water during flash evaporation is a certain part of DNT dissolved in the acid which passes under the condensation conditions of the water (Fixed point of the isomer mixture approx. 55 ° C) and the heat exchanger occupied. For Such relationships offer two possible solutions.

On the one hand, clocked heat exchangers can be used in such cases will. These are operated alternately and after assignment in the The rest phase melted. Problems with the assignment of the exchangers surface is the cooling capacity that quickly declines. Accordingly are clocked frequently. The melting of the capacitor that is at rest (heating up and cooling down again) requires additional energy.  

Another possibility for the condensation of vapors forming solids is the Mixing or injection condenser described (R.A. Vauck, H.A. Müller, Basic operations of chemical process engineering, 5th edition, VEB Leipzig 1962, P. 447). Below that is the introduction of the vapors into a spray of cold Water understood, with DNT in finely divided form for the above-mentioned case is deposited as a solid. It can both in the same as in Countercurrent to be worked. Because of the large necessary for this Water quantities, the water is usefully circulated and in Return branch cooled. To separate z. B. the DNT becomes a partial flow diverted. However, there is a risk of constipation Pipes and nozzles through organic components with low Melting point that tends to stick. The pure extraction of the DNT is also associated with an energy input, since it melted first and then must be separated liquid / liquid.

A much simpler and more elegant solution to the problem is the isothermal two - stage production of dinitrotoluene (Ullmann Encyclopedia of technical chemistry, 4th edition, volume 17, page 392, Verlag Chemie, Weinheim 1979). Here, a mixture of the isomeric mononitrotoluenes (MNT) is first produced, which in a second separate process step Dinitrotoluenes is implemented. The problem of the occupied heat exchanger at the Concentration of the acid in a vacuum is made by injecting MNT the first stage in the brothers fixed (DE-A 34 09 719). The injected MNT causes a lowering of the melting point of the DNT and thus ensures that the Vapors remain liquid even under the condensation conditions of the water. The organic phase isolated via phase separation is used in the reaction returned.

This elegant solution can be used in the process of single-stage, adiabatic Dinitration of toluene (EP-A 597 361) cannot be used because in Process there is no freely available MNT. This only occurs as not isolable intermediate in the reaction.

The task was to develop a continuous, adiabatic process for the production of To provide dinitrotoluene in which the problems encountered so far  or the complex process steps and additional energy expenditure be avoided.

The invention relates to a process for the continuous production of Dinitrotoluene isomer mixtures by nitration of toluene, which thereby is characterized in that toluene in one stage in a continuously operated Reactor using a nitrating acid consisting of (i) 80 to 100 % By weight of inorganic constituents, which essentially consist of 60 to 90 % By weight sulfuric acid, 1 to 20% by weight nitric acid and at least 5% by weight Compose water and (ii) 0 to 20 wt .-% organic components, the over 70% from dinitrotoluene isomers and the rest from by-products exist, while setting a molar ratio of nitric acid to toluene of at least 1.5: 1, preferably of at least 1.8: 1, particularly preferred of at least 1.9: 1 under adiabatic conditions, so that still small amounts of mononitrotoluene after nitriding in the Reaction mixture are present, the reactor continuously at a temperature reaction mixture leaving at least 120 ° C. by expansion evaporation, optionally with simultaneous heat input of at least 5% of the water freed by distillation, optionally up to 0.6 mol, preferably up to 0.3 mol, particularly preferably up to 0.2 mol, 50 to 100% by weight Nitric acid is mixed in, then into an upper product phase and a lower one Acid phase separates, the product phase worked up and the acid phase after Add 50 to 100% by weight nitric acid to the beginning of the process leads back.

Surprisingly, it was found that the condensation of the vapors can be carried out advantageously if the reaction is carried out in such a way that small amounts of MNT remain in the reaction product and the separation of the organic phase takes place only after the concentration of the acid. The minor Amounts of reaction product containing MNT occur immediately after leaving of the reactor in the concentration, the present MNT with the Water and small amounts of DNT is distilled off overhead. The relationship from MNT to DNT in the vapor condensate is 10: 1 to 1: 5, preferably 5: 1 to 1: 5. This MNT / DNT mixture ensures that the vapor condensate among the Condensation conditions of the water at the heat exchangers run smoothly.  

It is surprising here that almost the entire MNT distilled off with the vapors, so that the portion remaining in the distillation bottoms of MNT is very low and the DNT yield is only slightly reduced. The MNT / DNT mixture passing over with the vapors is separated off and into the Response returned.

This result is all the more surprising since process engineering calculations always result in significantly higher amounts for the residual MNT in the swamp.

Complete freedom from MNT of the nitriding product is achieved if after the step the concentration before phase separation small amounts of 50 to 100% by weight nitric acid, optionally with the simultaneous use of a Mixing unit, the reaction mixture are added.

Following the concentration step, the phases are separated carried out. This phase separation can occur at a significantly lower tempera take place than in the method claimed in EP-A 597 361. Thereby there are safety-related advantages. Furthermore, due to the reduced thermal load reduced amounts of by-products.

Due to the MNT content allowed in the reaction mixture, the requirements are to the reactor less. This no longer necessarily has to be full constant sales.

The residual amount of MNT required for the condensation of the vapors is determined by the substoichiometric reaction or by lowering the Acid concentration in the system reached. About reduced sulfuric acid concentration also reduces the solubility of the nitrided compounds and thus the amount of nitrated compounds in the acid cycle. Furthermore the acid no longer has to be concentrated as high after the reaction.

Due to the incomplete nitriding, the amount of Nitrating acid should be lower, since there is no absolutely complete dinitration must be respected, whereby u. a. a lower nitric acid pollution in the Waste water occurs.  

A molar ratio of nitric acid to toluene of over 2.5 is technically not sensible.

With a molar ratio of nitric acid to toluene of 2.0 Nitriding carried out so that MNT is still present in the reaction mixture. This can be the case, for example, by stopping the reaction prematurely or incomplete mixing of the reaction components can be achieved.

The invention is illustrated by the following examples.

example 1

248 g / h (2.692 mol / h) toluene and 9424 g / h (5.384 mol / h) nitrating acid (composition: 77.0 wt .-% H₂SO₄: 3.6 wt .-% HNO₃: 19.4 wt. -% H₂O) are each tempered to 120 ° C and brought to reaction in a tubular reactor under adiabatic conditions. The reaction mixture leaving the reactor at 160 ° C. contains 7.5% by weight of mononitrotoluene and is introduced into a vacuum of 30 mbar for concentration. The temperature of the sump drain was varied. The vapors leaving overhead are condensed on a cooler, the condensate running off in liquid form. The residual MNT content in the reaction mixture thus concentrated is at a bottom temperature of
110 ° C 1.05% by weight
115 ° C 0.44% by weight
120 ° C 0.21% by weight
125 ° C 0.17% by weight
130 ° C 0.10% by weight

Example 2

261 g / h (2.834 mol / h) toluene and 9424 g / h (5.384 mol / h) nitrating acid (composition as in Example 1) are each heated to 120 ° C. and reacted in a tubular reactor under adiabatic conditions. The reaction mixture leaving the reactor at 165 ° C. contains 13.6% by weight of mononitrotoluene and is introduced into a vacuum of 30 mbar. The temperature of the bottom effluent during the concentration was varied. The vapors leaving overhead are condensed on a cooler, the condensate running off in liquid form. The residual MNT content in the reaction mixture thus concentrated is at a bottom temperature of
110 ° C 3.34% by weight
115 ° C 1.33% by weight
120 ° C 0.48% by weight
125 ° C 0.21% by weight
130 ° C 0.12% by weight

Claims (1)

A process for the continuous production of dinitrotoluene isomers by the nitration of toluene, characterized in that toluene in one step in a continuously operated reactor using a nitrating acid consisting of (i) 80 to 100 wt .-% of inorganic components which are composed essentially of 60 to 90% by weight of sulfuric acid, 1 to 20% by weight of nitric acid and at least 5% by weight of water and (ii) 0 to 20% by weight of organic constituents which are 70 to 100% % consist of dinitritoluol isomers and the rest of by-products, with adjustment of a molar ratio of nitric acid to toluene of at least 1.5: 1, preferably 1.8: 1 under adiabatic conditions, so that even small amounts of mononitrotoluene after the Nitration present in the reaction mixture, the reaction mixture leaving the reactor continuously at a temperature of at least 120 ° C by flash evaporation, ge optionally with simultaneous supply of heat, at least 5% of the water is removed by distillation, optionally up to 0.6 mol, preferably up to 0.3 mol, of 50 to 100% by weight nitric acid is added, then separated into an upper product phase and a lower acid phase , the product phase worked up and the acid phase after addition of 50 to 100 wt .-% nitric acid returned to the beginning of the process.